The aim of this study is to determine the effects of pressure controlled ventilation during protective one lung ventilation on blood gases, airway pressures and hemodynamic variables compared with volume controlled ventilation.
One-lung ventilation (OLV) during thoracic surgery, in particular, video-assisted thoracic surgery is a standard practice to facilitate surgical exposure, but arterial hypoxemia has been a serious complication during one lung ventilation. Furthermore, recent studies have shown that one lung ventilation with a conventional tidal volume can involve lung injury associated with alveolar overdistension and high airway pressure. Therefore, lung protective ventilation with a low tidal volume during one lung ventilation has been suggested, and a recent study showed that protective ventilation during lung cancer surgery was associated with improved postoperative respiratory outcomes such as reduced incidence of acute lung injury and atelectasis. During protective one lung ventilation limiting airway pressure and using low tidal volume, it is important to provide uniform alveolar expansion and maintain adequate oxygenation. A previous study suggested that the decelerating inspiratory flow delivery used in pressure controlled ventilation improved ventilation/perfusion distribution and arterial oxygenation during one lung ventilation5. Moreover, according to a recent study during laparoscopic obesity surgery, pressure-controlled ventilation improved oxygenation compared with volume controlled ventilation, which was associated with higher instantaneous flow peaks and a better alveolar recruitment6. On the other hand, other studies showed that ventilatory mode during one lung ventilation did not affect arterial oxygenation. However, these studies were performed during mechanical ventilation using conventional tidal volume, and the effect of ventilatory mode during protective one lung ventilation on oxygenation has not been clearly determined yet.The aim of this study is to determine the effects of pressure controlled ventilation during protective one lung ventilation on blood gases, airway pressures and hemodynamic variables compared with volume controlled ventilation.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
PREVENTION
Masking
DOUBLE
Enrollment
34
One lung ventilation initiated with volume controlled ventilation(OLV-VCV) with an inspired oxygen fraction (FIO2) of 1.0, a tidal volume 6 mL/kg based on PBW and respiratory rate to maintain PaCO2 between 35-45 mmHg. After 30 min, the ventilator was switched to pressure controlled ventilation and the inspiratory pressure was adjusted to obtain the tidal volume 6 mL/kg. No external positive end-expiratory pressure was applied throughout the entire study. Arterial PaO2, PaCO2, peak inspiratory pressure (Ppeak), mean inspiratory pressure (Pmean), plateau inspiratory pressure (Pplateau) were recorded at the end of each ventilaroty mode.
One lung ventilation initiated with pressure controlled ventilation with an inspired oxygen fraction (FIO2) of 1.0, an inspiratory pressure provided the tidal volume 6 mL/kg based on PBW and respiratory rate to maintain PaCO2 between 35-45 mmHg. After 30 min, the ventilator was switched to VCV with a tidal volume 6 mL/kg based on PBW. No external positive end-expiratory pressure was applied throughout the entire study. Arterial PaO2, PaCO2, peak inspiratory pressure (Ppeak), mean inspiratory pressure (Pmean), plateau inspiratory pressure (Pplateau) were recorded at the end of each ventilaroty mode.
Seoul National University Bundang Hospital
Seongnam-si, Gyeonggi-do, South Korea
RECRUITINGarterial oxygenation differences
(1) during two-lung ventilation using VCV before initiation of OLV (baseline); (2) during OLV 30 min after the first randomized ventilation mode; (3) 30 min after the second ventilation mode; and (4) 30 min after reestablishing two-lung ventilation.
Time frame: four time points during operation
peak inspiratory pressure (Ppeak)
(1) during two-lung ventilation using VCV before initiation of OLV (baseline); (2) during OLV 30 min after the first randomized ventilation mode; (3) 30 min after the second ventilation mode; and (4) 30 min after reestablishing two-lung ventilation.
Time frame: four time points during operation
mean inspiratory pressure (Pmean)
(1) during two-lung ventilation using VCV before initiation of OLV (baseline); (2) during OLV 30 min after the first randomized ventilation mode; (3) 30 min after the second ventilation mode; and (4) 30 min after reestablishing two-lung ventilation.
Time frame: four time points during operation
plateau inspiratory pressure (Pplateau)
(1) during two-lung ventilation using VCV before initiation of OLV (baseline); (2) during OLV 30 min after the first randomized ventilation mode; (3) 30 min after the second ventilation mode; and (4) 30 min after reestablishing two-lung ventilation.
Time frame: four time points during operation
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